TY - JOUR
T1 - An engineered antibody fragment targeting mutant β-catenin via major histocompatibility complex I neoantigen presentation
AU - Miller, Michelle S.
AU - Douglass, Jacqueline
AU - Hwang, Michael S.
AU - Skora, Andrew D.
AU - Murphy, Michael
AU - Papadopoulos, Nickolas
AU - Kinzler, Kenneth W.
AU - Vogelstein, Bert
AU - Zhou, Shibin
AU - Gabelli, Sandra B.
N1 - Funding Information:
This work was supported by the Lustgarten Foundation (to B. V.), the BKI Cancer Genetics and Genomics Research Program (to B. V.), United States Department of Defense Grant CDMRP BC151831 (to S. B. G.), and National Institutes of Health Grants CA062924 (to S. B. G.), P30 CA006973 (to B. V.), The Virginia and D. K. Ludwig Fund for Cancer Research (to B. V. and K. W. K.) and the Commonwealth Fund (to S. Z.). B. V., K. W. K., and N. P. are founders of, hold equity in, and are consultants to Thrive Earlier Detection and Personal Genome Diagnostics. K. W. K. and N. P. are on the Board of Directors of Thrive Earlier Detection. S. Z. is a founder of, holds equity in, and serves as a consultant to Personal Genome Diagnostics, holds equity in Thrive Earlier Detection, and has a research agreement with BioMed Valley Discoveries. K. W. K and B. V. are consultants to Sysmex, Eisai, and CAGE Pharma and hold equity in CAGE Pharma. B. V. is also a consultant to Nexus, and K. W. K., B. V., S. Z., and N. P. are consultants to and hold equity in NeoPhore. Sysmex, Qiagen, Invitae, Personal Genome Diagnostics, Pap-Gene, Thrive Earlier Detection, BioMed Valley Discoveries, Pierce Biotechnology, Horizon Discovery, Life Technologies, as well as other companies, have licensed previously described technologies from Johns Hopkins University. B. V., K. W. K., S. Z., and N. P. are inventors on some of these technologies. Licenses to these technologies are or will be associated with equity or royalty payments to the inventors as well as to Johns Hopkins University. Patent applications on the work described in this paper have or may be filed by Johns Hopkins University. The terms of all these arrangements are being managed by Johns Hopkins University in accordance with its conflict of interest policies. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health. We acknowledge the use of the Eukaryotic Tissue Culture Facility at Johns Hopkins University and its manager Yana Li for her expertise in protein expression using mammalian cells. Work at the AMX (17-ID-1) and FMX (17-ID-2) beamlines was supported by NIGMS, National Institutes of Health, Grant P41GM111244 and by United States Department of Energy Office of Biological and Environmental Research Grant KP1605010, and the National Synchrotron Light Source II at Brookhaven National Laboratory is supported by the Department of Energy Office of Basic Energy Sciences under Contract DE-SC0012704 (KC0401040).
Funding Information:
Acknowledgments—We acknowledge the use of the Eukaryotic Tissue Culture Facility at Johns Hopkins University and its manager Yana Li for her expertise in protein expression using mammalian cells. Work at the AMX (17-ID-1) and FMX (17-ID-2) beamlines was supported by NIGMS, National Institutes of Health, Grant P41GM111244 and by United States Department of Energy Office of Biological and Environmental Research Grant KP1605010, and the National Synchrotron Light Source II at Brookhaven National Laboratory is supported by the Department of Energy Office of Basic Energy Sciences under Contract DE-SC0012704 (KC0401040).
Funding Information:
This work was supported by the Lustgarten Foundation (to B. V.), the BKI Cancer Genetics and Genomics Research Program (to B. V.), United States Department of Defense Grant CDMRP BC151831 (to S. B. G.), and National Institutes of Health Grants CA062924 (to S. B. G.), P30 CA006973 (to B. V.), The Virginia and D. K. Ludwig Fund for Cancer Research (to B. V. and K. W. K.) and the Commonwealth Fund (to S. Z.). B. V., K. W. K., and N. P. are founders of, hold equity in, and are consultants to Thrive Earlier Detection and Personal Genome Diagnostics. K. W. K. and N. P. are on the Board of Directors of Thrive Earlier Detection. S. Z. is a founder of, holds equity in, and serves as a consultant to Personal Genome Diagnostics, holds equity in Thrive Earlier Detection, and has a research agreement with BioMed Valley Discoveries. K. W. K and B. V. are consultants to Sysmex, Eisai, and CAGE Pharma and hold equity in CAGE Pharma. B. V. is also a consultant to Nexus, and K. W. K., B. V., S. Z., and N. P. are consultants to and hold equity in NeoPhore. Sysmex, Qiagen, Invitae, Personal Genome Diagnostics, Pap-Gene, Thrive Earlier Detection, BioMed Valley Discoveries, Pierce Biotech-nology, Horizon Discovery, Life Technologies, as well as other companies, have licensed previously described technologies from Johns Hopkins Uni-versity. B. V., K. W. K., S. Z., and N. P. are inventors on some of these tech-nologies. Licenses to these technologies are or will be associated with equity or royalty payments to the inventors as well as to Johns Hopkins University. Patent applications on the work described in this paper have or may be filed by Johns Hopkins University. The terms of all these arrange-ments are being managed by Johns Hopkins University in accordance with its conflict of interest policies. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.
Publisher Copyright:
© 2019 American Society for Biochemistry and Molecular Biology Inc.. All rights reserved.
PY - 2019/12/13
Y1 - 2019/12/13
N2 - Mutations in CTNNB1, the gene encoding β-catenin, are common in colon and liver cancers, the most frequent mutation affecting Ser-45 in β-catenin. Peptides derived from WT β-catenin have previously been shown to be presented on the cell surface as part of major histocompatibility complex (MHC) class I, suggesting an opportunity for targeting this common driver gene mutation with antibody-based therapies. Here, crystal structures of both the WT and S45F mutant peptide bound to HLA-A*03:01 at 2.20 and 2.45 Å resolutions, respectively, confirmed the accessibility of the phenylalanine residue for antibody recognition. Phage display was then used to identify single-chain variable fragment clones that selectively bind the S45F mutant peptide presented in HLA-A*03:01 and have minimal WT or other off-target binding. Following the initial characterization of five clones, we selected a single clone, E10, for further investigation. We developed a computational model of the binding of E10 to the mutant peptide- bound HLA-A3, incorporating data from affinity maturation as initial validation. In the future, our model may be used to design clones with maintained specificity and higher affinity. Such derivatives could be adapted into either cell-based (CAR-T) or protein-based (bispecific T-cell engagers) therapies to target cancer cells harboring the S45F mutation in CTNNB1.
AB - Mutations in CTNNB1, the gene encoding β-catenin, are common in colon and liver cancers, the most frequent mutation affecting Ser-45 in β-catenin. Peptides derived from WT β-catenin have previously been shown to be presented on the cell surface as part of major histocompatibility complex (MHC) class I, suggesting an opportunity for targeting this common driver gene mutation with antibody-based therapies. Here, crystal structures of both the WT and S45F mutant peptide bound to HLA-A*03:01 at 2.20 and 2.45 Å resolutions, respectively, confirmed the accessibility of the phenylalanine residue for antibody recognition. Phage display was then used to identify single-chain variable fragment clones that selectively bind the S45F mutant peptide presented in HLA-A*03:01 and have minimal WT or other off-target binding. Following the initial characterization of five clones, we selected a single clone, E10, for further investigation. We developed a computational model of the binding of E10 to the mutant peptide- bound HLA-A3, incorporating data from affinity maturation as initial validation. In the future, our model may be used to design clones with maintained specificity and higher affinity. Such derivatives could be adapted into either cell-based (CAR-T) or protein-based (bispecific T-cell engagers) therapies to target cancer cells harboring the S45F mutation in CTNNB1.
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U2 - 10.1074/jbc.RA119.010251
DO - 10.1074/jbc.RA119.010251
M3 - Article
C2 - 31690625
AN - SCOPUS:85076502489
SN - 0021-9258
VL - 294
SP - 19322
EP - 19334
JO - Journal of Biological Chemistry
JF - Journal of Biological Chemistry
IS - 50
ER -